JPH0756818B2 - Fireproof electrical cable connector - Google Patents

Description

Description: FIELD OF THE INVENTION The present invention relates to electrical cable splices that utilize a refractory inorganic fiber layer therein with a heat-shrinkable sleeve.

PRIOR ART According to the prior art, the general type of cable connector described above is widely used. Such a connector can easily be manufactured at the application site without the use of cable molding material. However, such a connector has not been used where a strong fire resistance is required. Since the cable sheath that forms the outer circumference of the cable core is usually plastic, and the shrink sleeve is also plastic, when a fire is affected, the cable sheath and sleeve are rapidly melted and destroyed. As a result, a short circuit is created between the core connections, ending the function of the cable.

Because of the poor fire resistance of the cable splicers described above, it has been preferred to completely discontinue use of such cable splicers and replace them with specialty cables that use a fire resistant cable sheath. And the special use of expensive special cables has been endured.

Plastic materials with increased fire resistance, such as highly halogenated plastics, or plastic materials containing fire-preventing additives (German published specification, offenlegungs schriften 15
69 123, 14 94 922) are known. However,
The fire resistance of such plastic materials is not very great. When such plastic materials are decomposed under the influence of fire, they give off harmful corrosive or toxic gases and vapors. Since contracted hoses or sleeves cannot be made from such materials, the use of such materials is limited to other structural types of cable splices.

An object of the invention is to provide a type of cable connector that can be manufactured in a way that does not adversely affect the possibility of simple manufacture and that, even under the influence of a fire, it can still be operated for a considerable time. Is the object of the present invention.

(Summary of the Invention) In the cable connector according to the present invention, the basic shape-retaining layer made of the refractory inorganic fiber material basically retains its shape even under the influence of a fire. Even if the components are melted or destroyed, accidental contact between the cores, especially short circuits, is avoided. Since layers of refractory fiber material are provided at the core connection points, these layers do not substantially prevent the dissipation of heat generated in the core connections during operation. The tightness of the core connections required in normal operation is ensured by the contracted hoses or sleeves as well as similar cable connections that are not fire resistant. The cable connector according to the invention can be manufactured easily in the field of use. This is because the sealing can be carried out by a usual method using a contracted hose or sleeve. No special precautions are required when installing the layers of fiber material. Therefore, the cable connector according to the present invention can perform a satisfactory work as expected even by an unskilled worker.

In cable splicers that do not use cable molding material, the cable enclosure is typically constructed using a shrink hose or sleeve that performs the sealing function between the cable sheath.
Such a type of cable connector, yet in accordance with the present invention, provides a layer of inorganic fiber material below the shrink sleeve of the cable enclosure, which layer is fire resistant and of substantially stable shape. With this, the fire resistance can be extremely increased. Therefore, in case of being affected by fire, the above-mentioned protective effect is first exerted in the cable surrounding part, so only after being affected for a long time,
The destructive action of the fire can proceed to the area of the core connection, whereupon the previously mentioned protective action of the attached layer of fiber material takes effect. In addition, the layer of refractory inorganic fiber mounted below the shrink sleeve in the cable envelope should be such that the heat applied to shrink the shrink sleeve will adversely affect the shrink sleeve of the core connection, which has already been completely shrunk. There is an advantage that you can not. On the contrary,
The thermal conductivity of many fiber materials is sufficient to dissipate the operating heat in the case of standard cable connections.

There are several possibilities for producing a substantially shape-retaining layer of inorganic fiber material. In general, sufficient shape stability is primarily due to the interconnectivity of the fibers, but retains some desirable deformability and resilience.

Refractory inorganic fiber materials are well known, for example, various types such as mat, wool, tape, etc. are commercially available, and many of these commercially available types are suitable for producing the fiber layer described above. is doing. It is especially convenient to make the layers of fiber material in banded form. Such bandages can be made very easily with wool, foil, tape, yarn, etc. A sufficient thickness of such a band seal provides particularly good shape stability, especially in critical regions over stressed metal parts such as crimp connectors or bare conductors.

It is also convenient to form the fiber layer in the form of a molded body. Fiber materials can be used in the curing paste for their fabrication.

The desired degree of shape stability of the fiber layer can also be obtained or improved by using a fire resistant retention device, such as a metal fastener that holds the fiber layer together. You can

Fiber materials are suitable for many refractory inorganic materials. In particular, glass fibers or ceramic fibers are known because they are easy to work with, and are commercially available in various shapes, for example, mat-shaped and non-spun wool-shaped. Ceramic fiber has the advantage of withstanding particularly high temperatures. A particularly suitable ceramic fiber material is that sold under the trade name "Trition Kaowool" by Morgan GmbH, a company located in Ratingen near Deyutsseldorf. The material does not change up to about 1400 ° C.

Inorganic fiber materials have the property of binding to each other without the use of a binder. This phenomenon is understood to be due to fiber interconnectivity, or molecular forces (Juan der Waals forces) or electrical forces. The fiber material "Trithione Kaowool" mentioned above exhibits this property in particular. When using this type of fiber material, the fibers in the layer of fiber material can be bound together without the use of a binder. Alternatively, of course, an embodiment is also possible in which the fibers are bound to one another in the layer of fiber material by means of a refractory inorganic binder. Sodium silicate is particularly suitable as a binder, it is not expensive and does not generate harmful gases under the influence of fire.

After preparing the fiber material layer for the core wire connection, it is desirable to prepare this fiber material layer on the core wire connection. To facilitate that, it is convenient to use a lubricant, such as silicon grease, which can also be a heat resistant material, below the layer of fiber material.

(Example) FIG. 1 shows a cable connector 1 for two medium-voltage three-core cables 3 and 5. Each cable has a cable sheath 7 and 9 and three insulated wires 11, 13, 15 respectively.
And 17, 19, 21 respectively.

The cable connector shown has a number of core connections corresponding to the number of cable cores, and thus three core connections in this case. Among those core wire connection portions, the core wire connection portion between the core wire 15 and the core wire 21 is omitted in FIG. 1 for clarity. Of the remaining two core wire connecting portions 23 and 25, a part of the core wire connecting portion 23 is shown by a cut surface, but it should be understood that other core wire connecting portions are designed correspondingly. Attached to the core connection 23 is a crimp connector 27, which forms an electrical contact between the bare ends 29 and 31 of the interconnection core. Each core wire connection is an electrical insulator and has a sealed core wire enclosure 33, 35
Equipped with. This uses shrink hoses or sleeves 37 and 39, respectively, in the illustrated embodiment. The overall cable connector is provided with a hermetically sealed cable enclosure 41 extending from one cable sheath 7 to the other cable sheath 9, using a shrink hose or sleeve 43 in the illustrated embodiment. To do.

In each core wire enclosure, basically a shape-stabilizing layer 45, that is, an inorganic fiber material having fire resistance is provided below the shrinking hose. In the illustrated embodiment, a layer 45 of fiber material.
Is made of tape-like non-spun wool-like bandages using the ceramic fiber material sold under the trade name of "Trithion Kaoool" by Morgan Co., Ltd. In this ceramic fiber material, the fibers are bound to each other without using a binder.

FIG. 2 is another embodiment corresponding to the embodiment shown in FIG. 1, but in order to avoid duplication, reference is made here to what has been described for FIG. Further, in FIG. 2, only two of the three core wire connecting portions are shown.

Further, in the cable connector shown in FIG. 2, each core wire connecting portion 223, 225 is provided with a core wire surrounding portion 233, 235, and a contracting hose 237, 239 is provided below the core wire connecting portion 223, 225, respectively. And layers 245 and 47 having fire resistance, respectively. However, these layers of fiber material are also held together, respectively, by heat resistant retainers in the form of steel clamps 49,51 and 53,55.
Furthermore, below the shrink hose 243, the cable enclosure 241 includes a layer 57 of inorganic fiber material. Layer 57 above
Is fire resistant and basically stable in shape. This further increases safety against fire, so that the shrink hose 243 of the cable envelope 237 will not shrink even if the already-contracted hoses 237 and 239 of the core envelopes 233 and 235 are not subjected to the allowable high heating. Be seen.

In the embodiment shown in FIG. 2, a heat-resistant lubricating material 59,51 such as silicon grease is included in each core outer circumference, and if necessary, a fiber material layer 245,47. Facilitate the movement of.

[Brief description of drawings]

FIG. 1 is a diagram of a cable connector according to the present invention,
FIG. 2 is a partial sectional view, and FIG. 2 is a view showing another embodiment corresponding to FIG. In FIG. 2, parts corresponding to those in FIG. 1 are designated by the same reference numerals with “2” prefixed. The drawings are not drawn to scale. (Explanation of symbols) 1 …… Cable connector 3,5 …… 3-core cable 7,9 …… Cable sheath 11,13,15,17,19,21 …… Insulated core wire 23,25,223,225 …… Core wire Connection part 27 …… Crimp connector 29,31 …… Bare end part 33,35,233,235 …… Core wire outer circumference 37,39,43,237,239,243 …… Shrinkable hose or sleeve 41,241 …… Cable outer circumference 45,47,57,245 …… Layers of fiber material 49,51,53,55 …… Steel fasteners 59,61 …… Heat resistant lubricating material

Claims (11)

[Claims] 1. An electrical cable connector including a plurality of core connections, each core connection comprising an electrically insulated hermetic core envelope including a layer of refractory fiber material on said core. And a shrinkable sleeve thereon, and a hermetically sealed cable envelope surrounding the core envelope extends from a first cable sheath to a second cable sheath, the layer of refractory fiber material being substantially Cable connector that maintains a stable shape. 2. The electric cable connector according to claim 1, wherein the hermetically sealed cable enclosing portion uses a layer of a refractory inorganic fiber material and a sleeve shrunk thereon. 3. The electric cable connector according to claim 1, wherein the layer of fiber material is in the form of a band. 4. An electrical cable connector according to claim 1, wherein the layer of fiber material is in the form of a molding. 5. The electrical cable connector of claim 3 which uses a heat resistant fastener to hold the layers of fiber material together. 6. An electrical cable connector as claimed in claim 1, wherein glass fiber is used for the layer of fiber material. 7. An electrical cable connector as claimed in claim 1 in which a ceramic fiber is used in the layer of fiber material. 8. The method according to claim 1, wherein a fiber having self-bonding property is used as the fiber material layer.
An electrical cable connector that does not use a binder for the layers. 9. The electric cable connector according to claim 1, wherein a fiber and a heat-resistant inorganic binder are used in the fiber material layer. 10. The electric cable connector according to claim 9, wherein sodium silicate is used as the binder. 11. The electrical cable connector according to claim 1, wherein the hermetically-enclosed core envelope uses a lubricating component below the fiber material layer.